Electrical switching apparatus and secondary disconnect assembly with cradle assembly alignment and positioning features therefor

ABSTRACT

A secondary disconnect assembly is for an electrical switching apparatus. The secondary disconnect assembly includes a mounting member and a cradle assembly coupled to the mounting member and being movable among a plurality of positions with respect to the mounting member. The cradle assembly includes an inner cradle. When the inner cradle is disposed in a first predetermined one of the positions, movement of the inner cradle is restricted with respect to the mounting member. When the inner cradle is moved toward a second predetermined one of the positions, the inner cradle moves independently with respect to the mounting member.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No.14/678,012, filed on Apr. 3, 2015, and entitled “ELECTRICAL SWITCHINGAPPARATUS AND SECONDARY DISCONNECT ASSEMBLY WITH CRADLE ASSEMBLYALIGNMENT AND POSITIONING FEATURES THEREFOR.”

BACKGROUND

1. Field

The disclosed concept relates generally to electrical switchingapparatus and, more particularly, to electrical switching apparatus,such as circuit breakers. The disclosed concept also relates to circuitbreaker secondary disconnect assemblies having cradle assembly alignmentand positioning features.

2. Background Information

Electrical switching apparatus, such as circuit breakers, provideprotection for electrical systems from electrical fault conditions suchas, for example, current overloads, short circuits, abnormal voltage andother fault conditions.

In power distribution systems, for example, power circuit breakers,which are also commonly referred to in the art as air circuit breakers,are often mounted within a switchgear enclosure either individually orin combination with other switchgear (e.g., without limitation, circuitswitching devices and circuit interrupters such as circuit breakers,contactors, motor starters, motor controllers and other loadcontrollers). Generally, there are two types or categories (i.e., sizesor configurations) of power circuit breakers, a relatively larger“draw-out” design, and a relatively smaller “fixed” design. The“draw-out” variety of power circuit breaker is movable with respect to adraw-out frame, also known as a cassette, whereas the “fixed” variety ofpower circuit breaker is generally fixed in position. Draw-out and fixedpower circuit breakers have secondary terminal assemblies, which aresimilar in design.

The secondary terminal assembly of a draw-out power circuit breaker, forexample, generally includes a plurality of terminal blocks, a mountingstructure (e.g., without limitation, an elongated DIN rail) for mountingthe terminal blocks, a movable cradle assembly, and a plurality ofaccessory plugs movable with the cradle assembly to electrically connectand disconnect from the terminal blocks. Thus, the secondary disconnectassembly allows the customer to establish a plurality of secondaryterminal connections, for example, to populate the circuit breaker witha variety of desired accessories or features. In this manner, thecustomer can relatively easily customize the circuit breaker for aparticular application. In addition, the secondary disconnect assemblyprovides a convenient mechanism to safely perform a test, such as forexample, testing the sequence of a circuit breaker control circuit orpowering an installed accessory to test its function before the circuitbreaker enters service. That is, the circuit breaker is movable among aCONNECT position corresponding to the circuit breaker being completelyinserted or installed within the cassette and electric power beingsupplied through both the primary and the secondary terminalconnections, a TEST position corresponding to the circuit breaker beingpartially drawn-out of the cassette and power being supplied throughonly the secondary terminal connections, and a DISCONNECT positioncorresponding to both the secondary terminal connections and primaryconnections being disconnected, for example, to permit the circuitbreaker to be completely withdrawn from the cassette to inspect, modifyor replace the circuit breaker.

The components of the secondary disconnect assembly must be suitablysupported and accurately aligned and positioned to ensure properinteraction (i.e., mating; de-mating) of the secondary terminal assemblycomponents for reliable operation of the circuit breaker.

There is room for improvement in electrical switching apparatus, such ascircuit breakers, and in secondary disconnect assemblies therefor.

SUMMARY

These needs and others are met by embodiments of the disclosed concept,which are directed to a secondary disconnect assembly for an electricalswitching apparatus, which among other benefits includes a number offeatures for improved alignment and positioning of assembly components.

As one aspect of the disclosed concept, a secondary disconnect assemblyis provided for an electrical switching apparatus. The secondarydisconnect assembly comprises a mounting member and a cradle assemblycoupled to the mounting member and being movable among a plurality ofpositions with respect to the mounting member, the cradle assemblycomprising an inner cradle. When the inner cradle is disposed in a firstpredetermined one of the positions, movement of the inner cradle isrestricted with respect to the mounting member. When the inner cradle ismoved toward a second predetermined one of the positions, the innercradle moves independently with respect to the mounting member.

The mounting member may be a terminal block mount structured to receivea plurality of terminal blocks. The terminal block mount may comprise afirst end, a second end disposed opposite and distal from the first end,a first side, and a second side disposed opposite the first side. Themounting member may include a first alignment post and a secondalignment post, wherein the first alignment post protrudes outwardlyfrom the first side of the terminal mounting block proximate the firstend of the terminal mounting block, and wherein the second alignmentpost protrudes outwardly from the first side of the terminal mountingblock proximate the second end of the terminal mounting block. The innercradle may comprise a first end and a second end disposed opposite anddistal from the first end of the inner cradle. The first alignment postmay removably engage a portion of the first end of the inner cradle andthe second alignment post may removably engage a portion of the secondend of the inner cradle. The first alignment post may include a firstelongated groove and the second alignment post may include a secondelongated groove, and the first end of the inner cradle may include afirst rib and the second end of the inner cradle may include a secondrib, wherein the first rib is movably disposed within the firstelongated groove and the second rib is movably disposed within thesecond elongated groove.

The first alignment post may further include a first molded barb and thesecond alignment post may further include a second molded barb. Thefirst end of the inner cradle may further include a first molded bossand the second end of the inner cradle may further include a secondmolded boss. The first predetermined position may be a latched positioncorresponding to the inner cradle being fixed in position with respectto the terminal block mount. When the inner cradle is disposed in thelatched position, the first molded barb may engage the first molded bossand the second molded barb may engage the second molded boss to resistmovement of the inner cradle with respect to the terminal block mount.

As another aspect of the disclosed concept, an electrical switchingapparatus comprises: a housing; and a secondary disconnect assemblycooperating with the housing, the secondary disconnect assemblycomprising a mounting member and a cradle assembly coupled to themounting member and being movable among a plurality of positions withrespect to the mounting member, the cradle assembly comprising an innercradle. When the inner cradle is disposed in a first predetermined oneof the positions, movement of the inner cradle is restricted withrespect to the mounting member. When the inner cradle is moved toward asecond predetermined one of the positions, the inner cradle movesindependently with respect to the mounting member.

BRIEF DESCRIPTION OF THE DRAWINGS

A full understanding of the disclosed concept can be gained from thefollowing description of the preferred embodiments when read inconjunction with the accompanying drawings in which:

FIG. 1 is an isometric view of an electrical switching apparatus andsecondary disconnect assembly therefor, in accordance with an embodimentof the disclosed concept;

FIG. 2 is an exploded isometric view of the secondary disconnectassembly of FIG. 1;

FIG. 3 is an exploded isometric view of the cradle assembly of thesecondary disconnect assembly of FIG. 2;

FIG. 4 is another exploded isometric view of portions of the secondarydisconnect assembly;

FIG. 5 is an enlarged view of a cradle assembly alignment andpositioning feature for the secondary disconnect assembly, in accordancewith an embodiment of the disclosed concept;

FIG. 6 is a top plan view of the cradle assembly alignment andpositioning feature of FIG. 5;

FIG. 7A is an isometric view showing portions of the secondarydisconnect assembly disposed in a first position;

FIG. 7B is an isometric view showing portions of the secondarydisconnect assembly disposed in a second position; FIG. 8 is anisometric partially exploded and partially in section view of portionsof the secondary disconnect assembly;

FIG. 9 is an isometric view of a terminal block for the secondarydisconnect assembly;

FIG. 10 is an end elevation partially in section view taken along line10-10 of FIG. 8;

FIG. 11 is an exploded isometric view showing a portion of the terminalblock mount of the secondary disconnect assembly and a terminal block;

FIG. 12A is an isometric view of the terminal block mount and terminalblock of FIG. 11, showing the terminal block in the process of beingmounted to the terminal block mount;

FIG. 12B is an isometric view of the terminal block mount and terminalblock of FIG. 12A, showing the terminal block after being mounted to theterminal block mount;

FIG. 13 is another isometric view of a terminal block, showing anaccessory plug installed therein;

FIG. 14 is a section view taken along line 14-14 of FIG. 13, modified toshow the accessory plug removed from the terminal block;

FIG. 15 is a top isometric view of the accessory plug of FIG. 14;

FIG. 16 is a bottom isometric view of the accessory plug of FIG. 15;

FIG. 17 is top plan view of the accessory plug of FIG. 15;

FIGS. 18-20 are isometric views of the cradle assembly and terminalblock mount, also showing a retention feature for the inner cradle;

FIG. 21 is a section view taken along line 21-21 of FIG. 20;

FIG. 22 is an enlarged view of a portion of the cradle assembly andretention feature therefor of FIG. 21, showing the inner cradle in thelatched position;

FIG. 23 is another enlarged view of the portion of the cradle assemblyand retention feature therefor of FIG. 22, showing the inner cradle inan unlatched position;

FIG. 24 is a bottom isometric view of the cradle assembly and terminalblock mount, also showing a correction feature for the inner cradle; and

FIG. 25 is another bottom isometric view of the cradle assembly andterminal block mount of FIG. 24, showing the inner cradle cooperatingwith the correction feature.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

For purposes of illustration, embodiments of the disclosed concept willbe described as applied to a non-limiting example embodiment of a“draw-out” power circuit breaker, although it will become apparent thatthey could also be applied to a wide variety of other types ofelectrical switching apparatus including, for example and withoutlimitation, “fixed” power circuit breakers.

Directional phrases used herein, such as, for example, clockwise,counterclockwise, left, right, up, down, front, back, top, bottom andderivatives thereof, relate to the orientation of the elements shown inthe drawings and are not limiting upon the claims unless expresslyrecited therein.

As employed herein, the term “fastener” refers to any suitableconnecting or tightening mechanism expressly including, but not limitedto, rivets, screws, bolts and the combinations of bolts and nuts (e.g.,without limitation, lock nuts) and bolts, washers and nuts.

As employed herein, the statement that two or more parts are “coupled”together shall mean that the parts are joined together either directlyor joined through one or more intermediate parts.

As employed herein, the term “number” shall mean one or an integergreater than one (i.e., a plurality).

FIG. 1 shows an electrical switching apparatus, such as for examplewithout limitation a power circuit breaker 2, which employs a secondarydisconnect assembly 100 in accordance with a non-limiting exampleembodiment of the disclosed concept. In the example of FIG. 1, the powercircuit breaker 2 includes a housing 4, which is movable with respect toa frame or cassette 6. In other words, the circuit breaker 2 can bedrawn or racked into and out of the cassette 6 to a variety of desiredpositions including, for example and without limitation, a DISCONNECTposition, a CONNECT position, and a TEST position (see, for example,FIG. 7B). It will be appreciated, therefore, that the disclosedsecondary disconnect assembly 100 provides a mechanism for automaticallymating (i.e., electrically connecting) and de-mating (electricallydisconnecting) a plurality of secondary terminal connections for thecircuit breaker 2.

Referring to FIG. 2, in one non-limiting example embodiment, thedisclosed secondary disconnect assembly 100 includes a terminal blockassembly 200 having a mounting member 202. A cradle assembly 300 iscoupled to the mounting member 202 and is movable among a plurality ofpositions (e.g., without limitation, CONNECT position; TEST position;DISCONNECT position) with respect to the mounting member 202. The cradleassembly 300 includes a cradle housing 302 and an inner cradle 304movably disposed within the cradle housing 302. The example mountingmember is a terminal block mount 202 structured to receive a pluralityof terminal blocks 400. The terminal block mount 202 includes a numberof protrusions 204,206 (two are shown). As will be described herein, theprotrusions 204,206 comprise alignment posts, which are structured toalign and guide the inner cradle 304 with respect to the terminal blockmount 202. Additionally, particularly unique to the disclosed secondarydisconnect assembly 100, when the inner cradle 304 is disposed in afirst predetermined position (e.g., when the inner cradle 304 isdisposed within the full range of the TEST position through the CONNECTposition), the alignment posts 204,206 also function to engage and lockthe inner cradle 304 to restrict undesired movement of the inner cradle304 with respect to the terminal block mount 202. In other words, thedisclosed secondary disconnect assembly 100 includes a mechanism forensuring proper mechanical support and positioning as well as alignmentof the components (e.g., without limitation, terminal block assembly200; inner cradle 304) of the secondary disconnect assembly 100.Further, the ability of the alignment posts 204,206 to engage and lockthe inner cradle 304 helps to ensure the movable components are properlylocked out, as desired, yet when the inner cradle 304 is moved toward asecond predetermined one of the positions (e.g., without limitation,DISCONNECT position), or is otherwise removed from the TEST position orCONNECT position, the alignment posts 204,206 are structured to releasethe inner cradle 304, as shown for example in FIG. 7A, such that theinner cradle 304 can move independently with respect to the terminalblock mount 202, as desired.

Continuing to refer to FIG. 2, and also to FIGS. 3-7B, the terminalblock mount 202 is structured to receive a plurality of terminal blocks400 (one terminal block 400 is shown in FIG. 2; see also FIGS. 9 and11-14). The example terminal block mount 202 is a single-piece moldedmember having opposing first and second ends 210,212 and opposing firstand second sides 220,222. The aforementioned protrusions are a firstalignment post 204 protruding outwardly from the first side 220 of theterminal mounting block 202 proximate the first end 210 thereof, and asecond alignment post 206 protruding outwardly from the first side 220of the terminal mounting block 202 proximate the second end 212 thereof.

As shown in the exploded view of FIG. 3, the inner cradle 304 has firstand second opposing ends 310,312. As best shown in FIGS. 6, 7A and 7B,the first alignment post 204 removably engages a portion of the firstend 310 of the inner cradle 304, and the second alignment post 206removably engages a portion of the second end 312 of the inner cradle304. The example secondary disconnect assembly 100 also includes anoptional comb 216. When such comb 216 is optionally employed, it isgenerally disposed between the terminal block assembly 200 and cradleassembly 300, as shown in FIG. 2. It will be appreciated, however, thatother non-limiting example embodiments (not shown) wherein no such combmember is required or desired, are contemplated by the disclosedconcept.

Referring to the enlarged views of FIGS. 5 and 11, it will beappreciated that the first and second alignment posts 204,206respectively include first and second elongated grooves 230,232. Theelongated grooves 230,232 are structured to receive corresponding ribs320,322 of the inner cradle 304, as shown in FIG. 6. More specifically,the first end 310 of the inner cradle 304 includes a first rib 320, andthe second end 312 of the inner cradle 304 includes a second rib 322.The first rib 320 is movably disposed within the first elongated groove230 of the first alignment post 204, and the second rib 322 is movablydisposed within the second elongated groove 232 of the second alignmentpost 206. In this manner, the alignment posts 204,206 serve to align,support and movably position and guide the inner cradle 304 with respectto the terminal block mount 202, as desired. This, in turn, facilitatesproper interaction among other components of the disclosed secondarydisconnect assembly 100 (e.g., without limitation, accessory plugs500,500′ of FIG. 2; see also accessory plug 500, shown in FIGS. 8, 10and 13-17).

As shown in FIGS. 5, 6, 11, 12A and 12B, the first and second elongatedgrooves 230,232 further include tapered or sloped entrances to furtherfacilitate proper alignment or constraint and guidance of the innercradle 304. Specifically, the first alignment post 204 includes a firstsloped segment 234, which cooperates with the inner cradle 304 tofacilitate vertical alignment and guidance of the first rib 320 into thefirst elongated groove 230, and a second sloped segment 244, whichfacilitates transverse (i.e., horizontal) alignment and guidance of thefirst rib 320 into the first elongated groove 230. Similarly, it will beappreciated that the second alignment post 206 has a substantiallysimilar structure including first and second sloped segments 236,246,which respectively facilitate vertical and horizontal alignment andguidance of the second rib 322 into the second elongated groove 232.

As shown, for example, in FIGS. 4, 6, 12A and 12B, the first alignmentpost 204 further includes a first molded barb 240 and the secondalignment post 206 further includes a second molded barb 242. The firstand second molded barbs 240,242 are structured to cooperate with firstand second molded bosses 330,332, respectively, which are disposed onthe inner cradle 304. More specifically, the first end 310 of the innercradle 304 includes a first molded boss 330 and the second end 312 ofthe inner cradle 304 includes a second molded boss 332. In the TESTposition, shown in FIG. 7B, which corresponds to a locked-out or latchedposition wherein the inner cradle 304 is locked in position with respectto the terminal block mount 202, the first molded barb 240 engages thefirst molded boss 330 and the second molded barb 242 engages the secondmolded boss 332, thereby resisting movement of the inner cradle 304 withrespect to the terminal block mount 202. It will be appreciated that theinner cradle 304 is also latched in the CONNECT position. When the innercradle 304 is removed from such latched position, for example, to theDISCONNECT position, the first and second molded barbs 240,242 arestructured to deflect outwardly to release the first and second moldedbosses 330,332, thereby releasing the inner cradle 304 so that it maymove independently with respect to the terminal block mount 202.

As shown in FIGS. 2, 3 and in hidden line drawing in FIG. 8, the examplecradle assembly 300 further includes a plurality of extension springs350. The extension springs 350 bias the inner cradle 304 toward thelatched position. The aforementioned locking capability afforded by themolded barbs 240,242 and corresponding molded bosses 330,332 serves tofurther assist or supplement the function of the extension springs 350,for example, to ensure the inner cradle 304 remains in the desiredpredetermined locked-out configuration with respect to the terminalblock mount 202, when desired.

As shown in FIGS. 2, 4, 7A, 7B and 11-12B, the terminal block mount 202of the example secondary disconnect assembly 100 further includes anumber of unique features to facilitate proper positioning and alignmentof secondary disconnect assembly components. For example and withoutlimitation, as previously discussed, the terminal block mount 202 ispreferably a single-piece molded member. In the example, shown, thesingle-piece molded member 202 includes first and second opposing edges250,252 and a plurality of parallel molded walls 260, which extendbetween the first and second edges 250,252 on the first side 220 of theterminal block 202, as shown. Each of the terminal blocks 400 (FIGS. 2,11, 12A and 12B) is structured to be aligned and secured between acorresponding pair of such parallel walls 260. Accordingly, among otherbenefits, the terminal block mount 202 further serves to provideimproved vertical and horizontal alignment and mechanical support of theterminal blocks 400.

Still further alignment and positioning accuracy is provided by yetanother unique feature of the single-piece molded terminal block mount202. Specifically, as shown in FIGS. 2, 4, 7A, 7B and 11-12B, thesingle-piece molded member 202 preferably further includes a pluralityof molded recesses 270, and each of the terminal blocks 400 preferablyincludes a molded protrusion 402 (best shown in FIG. 11). The moldedprotrusion 402 is structured to be aligned with, and secured within, acorresponding one of the molded recesses 270, which is disposed betweenthe aforementioned parallel molded walls 260. It will be appreciatedthat any known or suitable alternative number, shape, type orconfiguration of alignment and positioning feature(s) other than or inaddition to the molded recesses 270 and terminal block moldedprotrusions 402 could be employed, without departing from the scope ofthe disclosed concept. For example and without limitation, the moldedprotrusion or other feature (not shown) could be disposed instead on theterminal block mount to cooperate with a molded recess or other feature(not shown) that is disposed instead on the terminal block.

Accordingly, the disclosed secondary disconnect assembly 100advantageously provides a number of unique alignment and positioningfeatures, which among other benefits, serve to improve interaction amongthe components (e.g., without limitation, terminal block assembly 200;inner cradle 304) of the secondary disconnect assembly 100, therebyimproving function and reliability of the assembly, as well as overallfunction and reliability of the circuit breaker 2.

In addition, the secondary disconnect assembly 100 preferably includes anumber of error-proofing features (e.g., without limitation, firsterror-proofing features 420,422; second error-proofing features 520,522;third error-proofing features 362,364,366; fourth error-proofingfeatures 530,532,534) structured to ensure components (e.g., withoutlimitation, cradle assembly 300; terminal blocks 400; accessory plugs500,500′ (FIG. 2)); properly align and interact with one another. Forexample and without limitation, it is important to prevent an accessoryplug 500 from being inserted upside down into a terminal block 400, andto ensure the accessory plug 500 is properly disposed in the cradleassembly 300. Thus, the error-proofing features (e.g.,362,364,366;420,422;520,522,530,532,534) advantageously function asrejection features to reject insertion or connection of the accessoryplugs 500 unless they are correctly disposed in a specific predeterminedorientation (e.g., without limitation, the plug is disposed in thecorrect upright position, rather than inverted or upside down). In thismanner, damage is avoided that could otherwise occur from improperelectrical connection.

As previously discussed, the secondary disconnect assembly 100 includesa plurality of accessory plugs 500,500′ (only one accessory plug 500 isshown and described in detail), which electrically connect accessories600 (shown in simplified form in FIG. 2), when the accessory plugs500,500′ are removably inserted into corresponding terminal blocks 400.In accordance with one non-limiting example embodiment of the disclosedconcept, both the terminal block 400 and the accessory plug 500 includea plurality of error-proofing features 420,422 and 520,522,respectively, which prohibit insertion of the accessory plug 500 intothe terminal block 400 unless the accessory plug 500 is correctlydisposed in the aforementioned predetermined orientation, as shown forexample, in FIGS. 13 and 14.

More specifically, as best shown in FIGS. 9 and 10, the terminal block400 includes a number of receptacles 410,412 (two are shown) each havinga number of first error-proofing features 420,422, and the accessoryplug 500 includes a plug housing 502 having a number of seconderror-proofing features 520,522. When the accessory plug 500 iscorrectly disposed in the aforementioned predetermined orientation(e.g., without limitation, the plug is disposed in the correct uprightposition, rather than inverted or upside down), as shown for example inthe section view of FIG. 14, the second error-proofing features 520,522cooperate with (i.e., align with and receive) the first error-proofingfeatures 420,422 to permit insertion of the plug housing 502 into theterminal block 400, as shown, for example, in FIG. 13 (see alsoaccessory plugs 500,500′ of FIG. 2). In the example shown and describedherein, the first error-proofing features comprise a number of elongatedribs 420,422 each protruding into a corresponding one of the receptacles410,412 of the terminal block 400, as shown in FIG. 9, and the seconderror-proofing features comprise a number of corresponding elongatedslots 520,522 in the plug housing 502, as shown in FIG. 10. Accordingly,when the accessory plug 500 is correctly inserted into the terminalblock 400 in the predetermined orientation, the elongated ribs 420,422of the terminal block 400 are disposed in the corresponding elongatedslots 520,522 of the accessory plug housing 502. Otherwise, if the plughousing 502 is disposed in any other orientation, other than thepredetermined orientation shown in FIGS. 13 and 14, the error-proofingfeatures (e.g., 420,422;520,522) will reject (i.e., prohibit) insertion.

Continuing to refer to FIGS. 9 and 10, and also to FIGS. 15-17, it willbe appreciated that the plug housing 502 of the example secondarydisconnect assembly 100 includes a retaining portion 504, a first leg510 extending outwardly from the retaining portion 504, and a second leg512 extending outwardly from the retaining portion 504 opposite andspaced from the first leg 510. Each of the terminal block receptacles410,412 includes a first cavity 414 structured to receive the first leg510, and a second cavity 416 structured to receive the second leg 512.It will be appreciated that for simplicity of illustration and economyof disclosure, only one of the terminal block receptacles (e.g., firstreceptacle 410) will be described in detail herein. It will further beappreciated that the first receptacle 410 and any other receptacle(e.g., without limitation, second receptacle 412) of the terminal block400 may have the same or a different size and/or shape (not shown) andmay have any known or suitable alternative number, type and/orconfiguration of error-proofing features (not shown), without departingfrom the scope of the disclosed concept.

As best shown in FIG. 9, the first cavity 414 of the example terminalbock 400 includes a first elongated rib 420, and the second cavity 416includes a second elongated rib 422. As best shown in FIGS. 10 and 16,the first leg 510 of the example accessory plug housing 502 includes afirst elongated slot 520 for receiving the first elongated rib 420, andthe second leg 512 includes a second elongated slot 522 for receivingthe second elongated rib 422.

In one non-limiting embodiment, the first elongated rib 420 is disposedin the first location within a first cavity 414, and the secondelongated rib 422 is disposed in a second location within the secondcavity 416, wherein the first location of the first elongated rib 420 isdifferent from the second location of the second elongated rib 422. Forexample and without limitation, in FIG. 9, the first and second terminalblock cavities 414,416 each respectively include a top 430,432, a bottom434,436, a first sidewall 438,440, and a second sidewall 442,444. Thefirst elongated rib 420 is disposed on the bottom 434 of the firstcavity 414 substantially centered between the first and second sidewalls438,440 thereof, whereas the second elongated rib 422 is disposed on thebottom 436 of the second cavity 416 adjacent to a corresponding one ofthe first and second sidewalls 442,444 thereof. It will be appreciated,however, that alternative embodiments (not shown), for example, whereinthe error-proofing features are disposed in the same or similarlocations within the respective cavities (e.g., 414,416), yet stillfunction to effectively reject improper positioning (e.g., withoutlimitation, inverted or upside down) of accessory plugs 500, are alsocontemplated by the disclosed concept.

It will be appreciated with reference to FIG. 10 that the firstelongated slot 520 is positioned in a corresponding location on theunderside of the first leg 510 of the accessory plug housing 502 betweenthe first and second sides of the accessory plug housing 502, such thatit will receive the first elongated rib 420 if, and only if, theaccessory plug housing 502 is correctly disposed in the aforementionedpredetermined orientation. Likewise, it will be appreciated that theelongated slot 522 is disposed in a corresponding position on the bottomcorner of the second leg 512 of the accessory plug housing 502 adjacentto the first side of the accessory plug housing 502, such that it willreceive the second elongated rib 422 if, and only if, the accessory plughousing 502 is correctly disposed in the aforementioned predeterminedorientation.

Referring again to FIG. 8, still further error-proofing features arepreferably employed with respect to the aforementioned cradle assembly300 of the secondary disconnect assembly 100. Specifically, aspreviously discussed, the cradle assembly 300 includes a cradle housing302 and an inner cradle 304 movably disposed in the cradle housing 302.The inner cradle 304 includes first and second opposing ends 310,312 anda plurality of thru holes 360 (see also FIGS. 2-4, 7A and 7B) extendingthrough the inner cradle 304 between the first end 310 and the secondend 312. The thru holes 360 include a number of third error-proofingfeatures, which in the example shown and described herein, comprise analignment shoulder 362 and a number of flange seats 364,366. Theaccessory plug 500 is structured to be removably disposed in a fullyinstalled position within a corresponding one of the thru holes 360. Theaccessory plug housing 502 includes a number of fourth error-proofingfeatures, which in the example shown and described herein, comprise ashoulder recess 530 (FIGS. 10 and 16) and a number of flanges 532,534(FIGS. 8-9 and 13-17). The fourth error-proofing features (e.g., withoutlimitation, 530,532,534) and the third error-proofing features (e.g.,without limitation, 362,364,366) cooperate to prohibit the accessoryplug housing 502 from being disposed in the fully installed positionwithin the inner cradle 304, unless the accessory plug 500 is correctlydisposed in the aforementioned predetermined orientation.

More specifically, when the accessory plug housing 502 is correctlydisposed in the predetermined orientation and is fully installed withina corresponding thru hole 360 of the inner cradle 304, the alignmentshoulder 362 is structured to be disposed in the shoulder recess 530(FIGS. 10 and 16) of the accessory plug housing 502, and each of theflanges 532,534, which extend outwardly from the accessory plug housing502, is structured to be disposed in a corresponding one of the flangeseats 364,366 (both shown in FIG. 8) of the inner cradle 304. That is,in the example shown and described herein, the inner cradle 304 includesfirst and second flange seats 364,366 and the accessory plug housing 502includes first and second flanges 532,534. The flanges 532,534 arereceived within the first and second flange seats 364,366, respectively,to snap the plug housing 502 into position on the cradle assembly 300if, and only if, the accessory plug 500 is disposed in the correctorientation. Otherwise, the flange seats 364,366 and flanges 532,534, aswell as the aforementioned alignment shoulder 362 and correspondingshoulder recess 530, will serve to reject (i.e., prohibit) insertion ofthe accessory plug 500 into the fully installed position.

Accordingly, among other benefits, by virtue of the fact that theshoulder recess 530 extends substantially the entire length of theaccessory plug housing 502 (best shown in FIG. 16), the error-proofingdesign in accordance with the disclosed concept functions to reject animproperly oriented (e.g., inverted or upside down) accessory plug 500very early. That is, unlike prior art designs, the accessory plug 500will be rejected such that it cannot be inserted to a degree whereinunintended and undesired improper electrical connection (e.g., reversedpolarity) could potentially occur. Additionally, the disclosederror-proofing features are advantageously mutually exclusive. That is,they are designed to also secure their intended rejection functions toreject electrical connections between improperly positioned components,when used in combination with other existing secondary disconnectassembly systems or components (not shown).

Accordingly, it will be appreciated that the accessory plug 500 can onlybe fully installed so as to properly move with the cradle assembly 300and move into and out of proper electrical contact with thecorresponding terminal block 400, for example, to electrically connectand disconnect a corresponding accessory 600 (shown in simplified formin FIG. 2) if, and only if, the accessory plug 500 is correctly disposedin the aforementioned predetermined orientation with respect to theinner cradle 304, and fully installed in the corresponding thru hole 360thereof.

Referring to FIG. 10, it will be appreciated that the first flange 532of the example accessory plug housing 502 has a length 536 and thesecond flange 532 has a length 538, which is different than the length536 of the first flange 534. In other words, the first flange 532extends outwardly from the retaining portion 504 of the accessory plughousing 502 a length or distance 536, which is less than the length ordistance 538 that the second flange 534 extends outwardly from theretaining portion 504 of the accessory plug housing 502.

In accordance with another unique aspect of the disclosed concept, theterminal block 400 has a width 450, which is relatively wider thanconventional terminal block designs (not shown). That is, conventionalterminal blocks (not shown) are relatively thin such that only onecorresponding accessory plug (not shown) can be inserted andelectrically connected between the sides of the terminal block. Theexample terminal block 400, on the other hand, has a width 450 that isat least twice as wide. That is, the terminal block 400 has a pluralityof receptacles 410,412 (two are shown) disposed side-by-side in theterminal block 400 such that the terminal block 400 can receive aplurality of accessory plugs 500,500′ (both shown in FIG. 2)side-by-side within the width 450 (i.e., between opposing sides) of theterminal block 400. Among other benefits, this relatively wide terminalblock design serves to reduce overall manufacturing complexity and costdue to the reduced number of individual terminal blocks required.

Accordingly, it will be appreciated that the disclosed secondarydisconnect assembly 400 includes a number of error-proofing features(e.g., without limitation, 362,364,366,420,422,520,522,530,532,534),which among other benefits, function to ensure proper alignment andinteraction among the cradle assembly 300, terminal blocks 400, andaccessory plugs 500, thereby improving operation of the secondarydisconnect assembly 100 and avoiding damage that could otherwise occurto the circuit breaker 2 (FIG. 1) and/or circuit breaker accessories 600(shown in simplified form in FIG. 2).

As employed herein, the term “accessory” refers to any known or suitableelectrically connectable component, feature or device for use with thedisclosed secondary disconnect assembly and circuit breaker, includingfor example and without limitation, communications, control wiring, andthe like.

In addition to the foregoing, the exemplary disconnect assembly 100further includes a variety of additional mounting features and contactalignment features, which will now be discussed.

As shown in the exploded view of FIG. 11, the terminal block mount 202in accordance with non-limiting example embodiment of the disclosedconcept, includes a number of first mounting features 280,290,292, andthe terminal block 400 includes a number of second mounting features480,492,492. As will be discussed, the second mounting features480,490,492 cooperate with the first mounting features 280,290,292 toproperly align, mount and stabilize the terminal block 400 on theterminal block mount 202 (see, for example, FIG. 12A showing terminalblock 400 being installed on terminal block mount 202, and FIG. 12Bshowing the terminal block 400 fully installed or mounted on theterminal block mount 202). Furthermore, the aforementioned accessoryplugs 500 each include a number of contact alignment features540,542,550,552, which as will be discussed, are structured to align andguide the accessory plugs 500 into corresponding receptacles 410 of theterminal block 400 (see, for example, FIG. 13 showing accessory plug 500inserted into receptacle 410 of terminal block 400, and FIG. 14 showingaccessory plug 500 removed from but aligned with receptacle 410 of theterminal block 400).

More specifically, as shown in FIG. 14, the contact alignment features540,542,550,552 serve to align and guide the first leg 510 of theaccessory plug housing 502 into the first cavity 414 of the firstreceptacle 410 and to align and guide the second leg 512 of theaccessory plug housing 502 into the second cavity 416 of receptacle 410.In greater detail, referring to FIGS. 15-17, the first and second legs510,512 each respectively include a first end 514,515 disposed at ourabout the retaining portion 504, and a second end 516,517 disposedopposite and distal from the first end 514,515. The contact alignmentfeatures include a first tapered portion 540 disposed proximate thesecond end 516 of the first leg 510 and a second tapered portion 542disposed proximate the second end 517 of the second leg 512. Suchtapered portions 540,542 function to reduce the size of the second ends516,517 of the legs 510,512, respectively, which in turn provides moretolerance for correcting any initial misalignment with the correspondingcavities 414,416 of receptacle 410 of the terminal block 400. That is,the first tapered portion 540 cooperates with at least one of the top430, bottom 434, first sidewall 438, and second sidewall 442 of thefirst cavity 414 to guide the second end 516 of the first leg 510 intothe first cavity 414, and the second tapered portion 542 cooperates withat least one of the top 432, bottom 436, first sidewall 440, and secondsidewall 444 of the second cavity 416 to guide the second end 517 of thesecond leg 512 into the second cavity 416.

In addition, the example accessory plug 500 further includes a firsttapered nose 550, which extends outwardly from the second end 516 of thefirst leg 510, and a second tapered nose 552, which extends outwardlyfrom the second end 517 of the second leg 512, as best shown in FIGS. 15and 16. It will be appreciated that the tapered noses 550,552 furtherfacilitate contact alignment and mating by providing a localized“lead-in” to center and lead or guide the legs 510,512 intocorresponding cavities 414,416, respectively, of the terminal block 400.That is, because the tapered noses 550,552 extend beyond the openings atthe ends of the legs 510,512 of the accessory plug housing 502, they arecapable of further tapering to a reduced size that is smaller than thesize of such openings, as best shown in FIGS. 14-16. In other words,without such tapered noses 550,552, the amount of possible taper (i.e.,size reduction) would otherwise be limited by the size of the accessoryplug leg openings. The tapered noses 550,552 allow a taper beyond thatlimitation, thereby effectively achieving an even greater alignmenttolerance. In one non-limiting embodiment, the first tapered nose 550provides a lateral reduction in the size of the second end 516 of thefirst leg 510 of at least 1.0 mm to facilitate horizontal alignmentbetween the first and second sidewalls 438,442 of the first cavity 414and the second tapered nose 552 preferably likewise provides a lateralreduction in size of the second end 517 of the second leg 512 of atleast 1.0 mm to facilitate horizontal alignment between the first andsecond sidewalls 440,444 of the second cavity 416. In other words, asbest shown with reference to the top plan view of FIG. 17, each taperednose (e.g., without limitation, first tapered nose 550) extendslaterally inwardly a distance 560 of at least 1.0 mm. In this manner,the tapered noses 550,552 serve to provide corresponding additionalhorizontal alignment tolerance with respect to each of the cavitysidewalls (e.g., without limitation, first and second sidewalls 438,442of first cavity 414), which would have otherwise been limited by thewidth or size of the openings in the end of the accessory plug housing502.

Referring, for example, to FIGS. 9 and 14, it will be appreciated thatthe terminal block 400 preferably also includes a number of contactalignment features (452,454,456,458). In the example shown and describedherein, each of the first and second cavities 414,416 further includesat least one chamfer 452,454,456,458 disposed on a corresponding atleast one of the top 430,432, the bottom 434,436, the first sidewall438,440, and the second sidewall 442,444. Specifically, in the exampleshown and described herein, the first cavity 414 includes a top chamfer452 in the top 430 of the first cavity 414 and a bottom chamfer 454 inthe bottom 434 of the first cavity 414. The top and bottom chamfers452,454 cooperate with the first tapered portion 540 of the first leg510 to align and guide insertion of the first leg 510. Similarly, thesecond cavity 416 includes top and bottom chamfers 456,458 in the topand bottom 432,436, respectively, of the second cavity 416. Such top andbottom chamfers 456,458 cooperate with the second tapered portion 542 ofthe second leg 512 to align and guide insertion of the second leg 512into the second cavity 416.

The aforementioned cradle assembly 300 (FIGS. 2-8, 11, 12A and 12B)preferably also includes at least one contact alignment feature.Specifically, as previously discussed, the inner cradle 304 includes aplurality of thru holes 360 extending through the inner cradle 304between the first and second ends 310,312 thereof. Such thru holes 360are defined by a plurality of vertical walls 370, best shown in theenlarged partially in section view of FIG. 8. The vertical walls 370function to properly align and secure the accessory plug 500 in thecradle assembly 300 for proper movement and interaction (e.g., alignmentand electrical connection) with respect to the terminal block 400.

Referring again to FIG. 11, the example terminal block 400 has amounting side 460, a connection side 462 opposite the mounting side 460,an upper end 470, and a lower end 472 disposed opposite the upper end470. In the example shown and described herein, the aforementioned firstmounting feature(s) comprises a plurality of stabilizing projections280, each of which protrudes outwardly from the first side 220 of theterminal block mount 202 at or about the first edge 250 thereof. Theaforementioned second mounting feature(s) comprises a molded recess 480in the mounting side 460 of each terminal block 400 at or about theupper end 470 of the terminal block 400. Accordingly, when the terminalblock 400 is mounted on the terminal block mount 202, as shown in FIGS.12A and 12B, the molded recess 480 receives a corresponding one of thestabilizing projections 280 to align and stabilize the terminal block400 on the terminal block mount 202.

Additionally, the number of first mounting features preferably furthercomprises a first retention mechanism 290 disposed at or about the firstedge 250 of the terminal block mount 202, and a second retentionmechanism 292 disposed at or about the second edge 252 of the terminalblock mount 202, and the number of second mounting features preferablyfurther comprises a first molded catchment 490 disposed at the upper end470 of the terminal block 400, and a second molded catchment 492disposed on the lower end 472 of the terminal block 400. The firstretention mechanism 290 engages and retains the first molded catchment490, and the second retention mechanism 292 engages and retains thesecond molded catchment 492, as shown in FIGS. 12A and 12B.

It will be appreciated that such mounting features serve to furtheralign and secure terminal blocks 400 in the proper orientation on theterminal block mount 202. As previously discussed, further stability isprovided by the fact that the terminal blocks 400 are themselvesrelatively wider than (e.g., without limitation, up to twice as wide orwider) conventional terminal blocks (not shown). Furthermore, aspreviously disclosed, the example terminal block mount 202 preferablyfurther includes a plurality of parallel walls 260 extending between thefirst and second edges 250,252 of the terminal block mount 202 tofurther align and secure terminal blocks 400 therebetween.

Accordingly, among other benefits, the disclosed secondary disconnectassembly 100 includes a number of mounting features (e.g., withoutlimitation, 280,290,292,480,490,492 and a number of contact alignmentfeatures (e.g., without limitation,370,452,454,456,458,540,542,550,552), which improve component support,alignment and interaction.

In addition to the foregoing, the disclosed secondary disconnectassembly 100 preferably further includes a number of terminal retentionand correction features, which address and overcome known problems withprior art designs (not shown), such as premature unlatching of the innercradle and failure of the inner cradle to reliably return to the latched(i.e., home) position. Such issues can be caused, for example, by suchcontributing factors as friction on the inner cradle due to assemblyvariation, part misalignment, and relatively stiff accessory wiring,worn latching components, improper customer use, and the like. Ifpremature unplugging of the secondary terminal connections occurs or ifthe secondary terminal connections fail to properly align and mate, thecircuit breaker will not have any secondary control. As will now bediscussed, the disclosed concept overcomes these disadvantages and addsreliability to the system by providing a number of retention members372,374 (both shown in FIG. 21) structured to overcome issues associatedwith friction, thereby avoiding premature unplugging, as well as anumber of correction features (e.g., without limitation, stop members390,392 shown in FIGS. 21 and 24) to correctly align the inner cradle304 and ensure that it is latched when desired.

Referring to FIGS. 18-20, and the section view of FIG. 21, it will beappreciated that the example cradle assembly 300 preferably includes anumber of retention members 372,374, and at least one stop member390,392 (two are employed in the non-limiting example shown anddescribed herein). As previously discussed, the terminal block mount 202includes first and second alignment posts 204,206 structured to beremovably coupled to the first and second ends 310,312, respectively, ofthe inner cradle 304. The retention members 372,374 cooperate with thealignment posts 204,206, respectively, to retain the alignment posts204,206 in a desired position with respect to the inner cradle 304. Thestop members 390,392 cooperate with the inner cradle 304 to correctlyalign the inner cradle 304 with respect to the terminal block mount 202and facilitate proper positioning of the inner cradle 304 in the latched(i.e., home) position, as desired.

More specifically, continuing to refer to FIG. 21, as well as FIGS. 22and 23, each alignment post 206 is moveable among a first position inwhich the alignment post 206 is substantially straight and the moldedbarb 242 engages the corresponding molded boss or detent 332, as shownin FIGS. 21 and 22, and a second position in which the alignment post206 is deflected outwardly such that the molded barb 242 releases thecorresponding respective molded boss or detent 332, as shown in FIG. 23.In the first, undeflected position (FIGS. 21 and 22), the alignment post206 and, in particular, cooperation of the molded barb 242 with themolded boss or detent 332 on the end 212 of the inner cradle 304,resists movement of the inner cradle 304 with respect to the terminalblock mount 202 such that the inner cradle 304 moves with the terminalblock mount 202, but not independently with respect thereto. Conversely,in the second, deflected position shown in FIG. 23, the alignment post206 is deflected outwardly, such that the molded barb 242 disengages thecorresponding molded boss or detent 332, releasing the inner cradle 304to move independently with respect to terminal block mount 202. Theretention members, which in the example shown and described herein, arefirst and second spacers 372,374, prevent such outward deflection of thealignment posts 204,206 (both shown in FIG. 21) to the aforementionedsecond, deflected position (FIG. 23), unless and until such outwarddeflection is desired. In this manner, the spacers 372,374 effectivelyresist premature release of the inner cradle 304.

It will be appreciated that for ease of illustration and economy ofdisclosure, only one spacer 374 has been shown and described in detailherein. It will be appreciated, however, that the other spacer 372 (FIG.21) is substantially similar in both structure and function.

As shown in FIG. 22, the spacer 374 extends inwardly from the interior306 of the cradle housing 302 towards the corresponding end 312 of theinner cradle 304. Thus, the spacers 372,374 function to reduce the spacebetween the corresponding alignment posts 204,206 and the interior 306of the cradle housing 302, when the alignment posts 204,206,respectively, extend between the corresponding spacer 372,374 and firstor second end 310,312 of the inner cradle 304. That is, less space isprovided such that undesired outward deflection of the alignment posts204,206 is resisted, which, in turn, functions to prevent prematurerelease of inner cradle 304, as previously discussed.

Continuing to refer to FIGS. 22 and 23, each spacer 374 preferablycomprises an elongated molded member, including a deflection edge 376.The deflection edge 376 is structured to cooperate with a correspondingdeflection surface 294 of the corresponding alignment post 206. Theexample deflection surface 294 is a ramped surface on the end of thealignment post 206 generally opposite the molded barb 242. Accordingly,when the terminal block mount 202 moves toward the latched position withrespect to the inner cradle 304, the ramped surface 294 engages thedeflection edge 376 of the spacer 374, as shown in FIG. 23. As thealignment post 206 continues to move (e.g., to the left from theperspective of FIG. 22), the deflection edge 376 slides along the rampedsurface 294 deflecting the alignment post 206 inwardly and moving themolded barb 242 toward engagement with the corresponding molded boss ordetent 332 (see, latched (i.e., home) position of FIG. 22). Accordingly,it will be appreciated that the end of each alignment post 206, inaccordance with the disclosed concept, incorporates a unique shape tofacilitate desired cooperation (e.g., without limitation, deflection) ofthe alignment post 206 with respect to components of the cradle assembly300 (e.g., without limitation, interior 306 of cradle housing 302; innercradle 304; molded boss or detent 332; retention member or space 374).In this manner, the inner cradle 304 remains in the latched (i.e., home)position, or is properly returned to such latched position, as desiredfor proper and reliable mating of the secondary terminal connections.

Referring to FIGS. 24 and 25, the aforementioned correction feature,which in the example shown and described herein is a pair of molded stopmembers 390,392 extending inwardly from the interior 306 of the cradlehousing 302, will now be described in greater detail. Specifically, theinner cradle 304 further includes a stop edge 308, which moves into(FIG. 25) and out of (FIG. 24) engagement with the stop members 390,392.In the non-limiting example embodiment shown and described, the firstmolded stop 390 and the second molded stop 392 are spaced apart fromeach other, as shown in FIG. 24. Such spaced apart relationship, amongother benefits, serves an alignment function. More specifically, whenthe stop edge 308 of the inner cradle 304 abuts both of the first moldedstop 390 and the second molded stop 392, as shown in FIG. 25, the innercradle 304 is correctly aligned with respect to the first and secondalignment posts 204,206 and, therefore, with respect to the terminalblock mount 202.

In addition to facilitating proper alignment, for example, when theinner cradle 304 is skewed while racking the circuit breaker 2 (FIG. 1)into a cassette 6 (FIG. 1), the correction features (e.g., molded stopmembers 390,392) also serve a number of other advantageous functions.For example, when the stop edge 308 (FIGS. 21-25) engages the moldedstop members 390,392 (see FIG. 25), continued movement will result inthe inner cradle 304 being moved toward and into the latched position,which allows the cradle assembly 300 to be reset when the circuitbreaker 2 is racked back out of the cassette 6. That is, the correctionfeatures (e.g., molded stop members 390,392) will continue to drive thesecondary electrical contacts to their mated position when the circuitbreaker 2 reaches the CONNECT position. This advantageously ensures fullengagement of the secondary contacts is established when the circuitbreaker 2 is fully connected to primary and secondary power.

Accordingly, the disclosed secondary disconnect assembly 100 includes anumber of terminal retention and correction features that facilitateproper latching, unlatching and re-latching of the inner cradle 304 andestablish correct alignment and movement for effective and reliablemating of secondary terminal connections.

While specific embodiments of the disclosed concept have been describedin detail, it will be appreciated by those skilled in the art thatvarious modifications and alternatives to those details could bedeveloped in light of the overall teachings of the disclosure.Accordingly, the particular arrangements disclosed are meant to beillustrative only and not limiting as to the scope of the disclosedconcept which is to be given the full breadth of the claims appended andany and all equivalents thereof.

What is claimed is:
 1. A secondary disconnect assembly for an electricalswitching apparatus, said secondary disconnect assembly comprising: amounting member; and a cradle assembly coupled to said mounting memberand being movable among a plurality of positions with respect to saidmounting member, said cradle assembly comprising an inner cradle,wherein, when said inner cradle is disposed in a first predetermined oneof said positions, movement of said inner cradle is restricted withrespect to said mounting member, and wherein, when said inner cradle ismoved toward a second predetermined one of said positions, said innercradle moves independently with respect to said mounting member.
 2. Thesecondary disconnect assembly of claim 1 wherein said mounting member isa terminal block mount structured to receive a plurality of terminalblocks; wherein said terminal block mount comprises a first end, asecond end disposed opposite and distal from the first end, a firstside, and a second side disposed opposite the first side; wherein saidmounting member includes a first alignment post and a second alignmentpost; wherein said first alignment post protrudes outwardly from thefirst side of said terminal mounting block proximate the first end ofsaid terminal mounting block; and wherein said second alignment postprotrudes outwardly from the first side of said terminal mounting blockproximate the second end of said terminal mounting block.
 3. Thesecondary disconnect assembly of claim 2 wherein said inner cradlecomprises a first end and a second end disposed opposite and distal fromthe first end of said inner cradle; wherein said first alignment postremovably engages a portion of the first end of said inner cradle; andwherein said second alignment post removably engages a portion of thesecond end of said inner cradle.
 4. The secondary disconnect assembly ofclaim 3 wherein said first alignment post includes a first elongatedgroove; wherein said second alignment post includes a second elongatedgroove; wherein the first end of said inner cradle includes a first rib;wherein the second end of said inner cradle includes a second rib;wherein said first rib is movably disposed within said first elongatedgroove; and wherein said second rib is movably disposed within saidsecond elongated groove.
 5. The secondary disconnect assembly of claim 4wherein said first alignment post and said second alignment post eachfurther include a first sloped segment and a second sloped segment;wherein said first sloped segment of said first alignment postcooperates with said inner cradle to facilitate vertical alignment andguidance of said first rib into said first elongated groove; whereinsaid second sloped segment of said first alignment post cooperates withsaid inner cradle to facilitate transverse alignment and guidance ofsaid second rib into said first elongated groove; wherein said firstsloped segment of said second alignment post cooperates with said innercradle to facilitate vertical alignment and guidance of said second ribinto said second elongated groove; and wherein said second slopedsegment of said second alignment post cooperates with said inner cradleto facilitate transverse alignment and guidance of said second rib intosaid second elongated groove.
 6. The secondary disconnect assembly ofclaim 3 wherein said first alignment post further includes a firstmolded barb; wherein said second alignment post further includes asecond molded barb; wherein the first end of said inner cradle furtherincludes a first molded boss; wherein the second end of said innercradle further includes a second molded boss; wherein said firstpredetermined one of said positions is a latched position correspondingto said inner cradle being fixed in position with respect to saidterminal block mount; and wherein, when said inner cradle is disposed insaid latched position, said first molded barb engages said first moldedboss and said second molded barb engages said second molded boss toresist movement of said inner cradle with respect to said terminal blockmount.
 7. The secondary disconnect assembly of claim 6 wherein, whensaid inner cradle is removed from said latched position, said firstmolded barb is structured to deflect outwardly to release said firstmolded boss and said second molded barb is structured to deflectoutwardly to release said second molded boss, thereby releasing saidcradle assembly to move independently with respect to said terminalblock mount.
 8. The secondary disconnect assembly of claim 6 whereinsaid inner cradle further comprises a plurality of extension springs;and wherein said extension springs bias said inner cradle toward saidlatched position.
 9. The secondary disconnect assembly of claim 2wherein said terminal block mount is a single-piece molded member;wherein said single-piece molded member further comprises a first edge,a second edge disposed opposite the first edge, and a plurality ofparallel walls extending between the first edge and the second edge onthe first side of said terminal block mount; and wherein each of saidterminal blocks is structured to be aligned and secured between acorresponding pair of said parallel walls.
 10. The secondary disconnectassembly of claim 9 wherein said single-piece molded member furthercomprises a plurality of molded recesses; and wherein each of saidterminal blocks includes a molded protrusion structured to be alignedwith and secured within a corresponding one of said molded recesses. 11.An electrical switching apparatus comprising: a housing; and a secondarydisconnect assembly cooperating with said housing, said secondarydisconnect assembly comprising: a mounting member, and a cradle assemblycoupled to said mounting member and being movable among a plurality ofpositions with respect to said mounting member, said cradle assemblycomprising an inner cradle, wherein, when said inner cradle is disposedin a first predetermined one of said positions, movement of said innercradle is restricted with respect to said mounting member, and wherein,when said inner cradle is moved toward a second predetermined one ofsaid positions, said inner cradle moves independently with respect tosaid mounting member.
 12. The electrical switching apparatus of claim 11wherein said mounting member is a terminal block mount structured toreceive a plurality of terminal blocks; wherein said terminal blockmount comprises a first end, a second end disposed opposite and distalfrom the first end, a first side, and a second side disposed oppositethe first side; wherein said mounting member includes a first alignmentpost and a second alignment post; wherein said first alignment postprotrudes outwardly from the first side of said terminal mounting blockproximate the first end of said terminal mounting block; and whereinsaid second alignment post protrudes outwardly from the first side ofsaid terminal mounting block proximate the second end of said terminalmounting block.
 13. The electrical switching apparatus of claim 12wherein said inner cradle comprises a first end and a second enddisposed opposite and distal from the first end of said inner cradle;wherein said first alignment post removably engages a portion of thefirst end of said inner cradle; and wherein said second alignment postremovably engages a portion of the second end of said inner cradle. 14.The electrical switching apparatus of claim 13 wherein said firstalignment post includes a first elongated groove; wherein said secondalignment post includes a second elongated groove; wherein the first endof said inner cradle includes a first rib; wherein the second end ofsaid inner cradle includes a second rib; wherein said first rib ismovably disposed within said first elongated groove; and wherein saidsecond rib is movably disposed within said second elongated groove. 15.The electrical switching apparatus of claim 14 wherein said firstalignment post and said second alignment post each further include afirst sloped segment and a second sloped segment; wherein said firstsloped segment of said first alignment post cooperates with said innercradle to facilitate vertical alignment and guidance of said first ribinto said first elongated groove; wherein said second sloped segment ofsaid first alignment post cooperates with said inner cradle tofacilitate transverse alignment and guidance of said second rib intosaid first elongated groove; wherein said first sloped segment of saidsecond alignment post cooperates with said inner cradle to facilitatevertical alignment and guidance of said second rib into said secondelongated groove; and wherein said second sloped segment of said secondalignment post cooperates with said inner cradle to facilitatetransverse alignment and guidance of said second rib into said secondelongated groove.
 16. The electrical switching apparatus of claim 13wherein said first alignment post further includes a first molded barb;wherein said second alignment post further includes a second moldedbarb; wherein the first end of said inner cradle further includes afirst molded boss; wherein the second end of said inner cradle furtherincludes a second molded boss; wherein said first predetermined one ofsaid positions is a latched position corresponding to said inner cradlebeing fixed in position with respect to said terminal block mount; andwherein, when said inner cradle is disposed in said latched position,said first molded barb engages said first molded boss and said secondmolded barb engages said second molded boss to resist movement of saidinner cradle with respect to said terminal block mount.
 17. Theelectrical switching apparatus of claim 16 wherein, when said innercradle is removed from said latched position, said first molded barb isstructured to deflect outwardly to release said first molded boss andsaid second molded barb is structured to deflect outwardly to releasesaid second molded boss, thereby releasing said inner assembly to moveindependently with respect to said terminal block mount.
 18. Theelectrical switching apparatus of claim 16 wherein said cradle assemblyfurther comprises a plurality of extension springs; and wherein saidextension springs bias said inner cradle toward said latched position.19. The electrical switching apparatus of claim 12 wherein said terminalblock mount is a single-piece molded member; wherein said single-piecemolded member further comprises a first edge, a second edge disposedopposite the first edge, and a plurality of parallel walls extendingbetween the first edge and the second edge on the first side of saidterminal block mount; and wherein each of said terminal blocks isstructured to be aligned and secured between a corresponding pair ofsaid parallel walls.
 20. The electrical switching apparatus of claim 19wherein said single-piece molded member further comprises a plurality ofmolded recesses; and wherein each of said terminal blocks includes amolded protrusion structured to be aligned with and secured within acorresponding one of said molded recesses.